Hirotake Yamaguchi scite author profile

Additional targets of CodY, a GTP-activated repressor of early stationary-phase genes in Bacillus subtilis, were identified by combining chromatin immunoprecipitation, DNA microarray hybridization, and gel mobility shift assays. The direct targets of CodY newly identified by this approach included regulatory genes for sporulation, genes that are likely to encode transporters for amino acids and sugars, and the genes for biosynthesis of branched-chain amino acids.Bacteria have evolved a variety of mechanisms to accommodate gene expression to changes in nutritional availability. Some of these mechanisms are specific to a particular gene or operon. In other cases, regulatory proteins control large groups of genes of related function, such as the nitrogen metabolism genes regulated by the Ntr system in enteric bacteria (43) and by TnrA in Bacillus subtilis (17) and the carbon metabolism genes regulated by CcpA in gram-positive bacteria (13) and catabolic gene activator protein-cyclic AMP complex in gram-negative bacteria (59). Even broader forms of regulation are mediated by the leucine-responsive protein (Lrp) of gram-negative bacteria and the sigma-B protein of B. subtilis. Lrp and sigma-B control the transcription of operons that have diverse functions but have a common need to be expressed under a particular set of environmental conditions (50, 54). Lrp regulates the biosynthesis of leucine, isoleucine, valine, serine, glycine, and glutamate; the degradation of serine and threonine; transport of peptides, amino acids, and sugars; and production of fimbriae in response to the availability of leucine and serine (50). Sigma-B activates transcription of a host of genes when cells are exposed to excessive heat, ethanol, salt, or acid (54). Sigma-B responds through a complex, multibranched signal transduction pathway.The B. subtilis CodY protein also has broad effects on gene expression. CodY is a GTP-binding repressor of several genes that are normally quiescent when cells are growing in a rich medium (57). A high concentration of GTP activates CodY as a repressor (57). When the growth rate of B. subtilis slows down because of limitation of the carbon or nitrogen or phosphorus source, the GTP level drops (39, 40), CodY loses repressing activity, and targets of CodY repression are transcribed. The known targets of CodY in B. subtilis include the genes that encode transport systems for dipeptides (dpp) (65) and ␥-aminobutyrate (gabP) (16); catabolic pathways for acetate (acsA) (S. H. Fisher, personal communication), urea (ureABC) (71), histidine (hut) (18), arginine (rocABC and roc-DEF) (B. Belitsky, personal communication), and branchedchain keto acids (the bkd operon) (12); an enzyme of surfactin synthesis (srfAA) (63); the transcription factor for DNA uptake genes (comK) (63); a ComA aspartyl phosphate phosphatase and its inhibitor (rapC-phrC) (37); motility and chemotaxis (hag, fla/che) (45; F. Bergara, C. Ibarra, J. Iwamasa, R. Aguilera, and L. M. Màrquez-Magaña, submitted for publication); and aconitase (citB) (3...

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Combined transcriptome and proteome analysis as a powerful approach to study genes under glucose repression in Bacillus subtilis

Yoshida

Kobayashi²,

Miwa³

et al. 2001

225

199

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We used 2D protein gel electrophoresis and DNA microarray technologies to systematically analyze genes under glucose repression in B:acillus subtilis. In particular, we focused on genes expressed after the shift from glycolytic to gluconeogenic at the middle logarithmic phase of growth in a nutrient sporulation medium, which remained repressed by the addition of glucose. We also examined whether or not glucose repression of these genes was mediated by CcpA, the catabolite control protein of this bacterium. The wild-type and ccpA1 cells were grown with and without glucose, and their proteomes and transcriptomes were compared. 2D gel electrophoresis allowed us to identify 11 proteins, the synthesis of which was under glucose repression. Of these proteins, the synthesis of four (IolA, I, S and PckA) was under CcpA-independent control. Microarray analysis enabled us to detect 66 glucose-repressive genes, 22 of which (glmS, acoA, C, yisS, speD, gapB, pckA, yvdR, yxeF, iolA, B, C, D, E, F, G, H, I, J, R, S and yxbF ) were at least partially under CcpA-independent control. Furthermore, we found that CcpA and IolR, a repressor of the iol divergon, were involved in the glucose repression of the synthesis of inositol dehydrogenase encoded by iolG included in the above list. The CcpA-independent glucose repression of the iol genes appeared to be explained by inducer exclusion.

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Whole-Genome Analysis of Genes Regulated by theBacillus subtilisCompetence Transcription Factor ComK

et al. 2002

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The Bacillus subtilis competence transcription factor ComK is required for establishment of competence for genetic transformation. In an attempt to study the ComK factor further, we explored the genes regulated by ComK using the DNA microarray technique. In addition to the genes known to be dependent on ComK for expression, we found many genes or operons whose ComK dependence was not known previously. Among these genes, we confirmed the ComK dependence of 16 genes by using lacZ fusions, and three genes were partially dependent on ComK. Transformation efficiency was significantly reduced in an smf disruption mutant, although disruption of the other ComK-dependent genes did not result in significant decreases in transformation efficiency. Nucleotide sequences similar to that of the ComK box were found for most of the newly discovered genes regulated by ComK.

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Comprehensive DNA Microarray Analysis of Bacillus subtilis Two-Component Regulatory Systems

et al. 2001

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It has recently been shown through DNA microarray analysis of Bacillus subtilis two-component regulatory systems (DegS-DegU, ComP-ComA, and PhoR-PhoP) that overproduction of a response regulator of the two-component systems in the background of a deficiency of its cognate sensor kinase affects the regulation of genes, including its target ones. The genome-wide effect on gene expression caused by the overproduction was revealed by DNA microarray analysis. In the present work, we newly analyzed 24 two-component systems by means of this strategy, leaving out 8 systems to which it was unlikely to be applicable. This analysis revealed various target gene candidates for these two-component systems. It is especially notable that interesting interactions appeared to take place between several two-component systems. Moreover, the probable functions of some unknown two-component systems were deduced from the list of their target gene candidates. This work is heuristic but provides valuable information for further study toward a comprehensive understanding of the B. subtilis two-component regulatory systems. The DNA microarray data obtained in this work are available at the KEGG Expression Database website (http://www.genome.ad.jp/kegg/expression).

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Identification of additional TnrA‐regulated genes of Bacillus subtilis associated with a TnrA box

Yoshida

Yamaguchi

Kinehara

et al. 2003

Molecular Microbiology

133

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SummaryBacillus subtilis TnrA is a global regulator that responds to the availability of nitrogen sources and both activates and represses many genes during nitrogen-limited growth. In order to obtain a holistic view of the gene regulation depending on TnrA, we performed a genome-wide screening for TnrAregulated genes associated with a TnrA box. A combination of DNA microarray hybridization and a genome-wide search for TnrA boxes allowed us to find 36 TnrA-regulated transcription units associated with a putative TnrA box. Gel retardation assaying, using probes carrying at least one putative TnrA box and the deletion derivatives of each box, indicated that 17 out of 36 transcription units were likely TnrA targets associated with the TnrA boxes, two of which ( nasA and nasBCDEF ) possessed a common TnrA box. The sequences of these TnrA boxes contained a consensus one, TGTNANAWWWTMTNACA. The TnrA targets detected in this study were nrgAB , pucJKLM , gln-QHMP , nasDEF , oppABCDF , nasA , nasBCDEF and ywrD for positive regulation, and gltAB , pel , ywdIJK , yycCB , yttA , yxkC , ywlFG , yodF and alsT for negative regulation, nrgAB and gltAB being well-studied TnrA targets. It was unexpected that the negatively regulated TnrA targets were as many as the positively regulated targets. The physiological role of the TnrA regulon is discussed.

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